DE102008046335B4 - Retractable contact bar protection and method - Google Patents

Abstract

Electronic device comprising:
a housing (24);
a contact rod (20) having a first end (22) and a second end, the second end being electrically coupled to a circuit operable to apply a voltage to the contact rod (20), the contact rod (20) and the Circuitry mounted to the housing (24) with the first end (22) projecting outwardly from the housing (24);
an insulating sleeve (30) slidably mounted over the contact rod (20); and
a latching mechanism (38) engaging the sleeve (30) and selectively engaging the sleeve (30) in a first position in which the sleeve (30) extends beyond the first end (22) and in a second position in the sleeve (30) is positioned below the first end (22) holds.

Description

TECHNICAL AREA

These This invention relates to electrical test equipment and more particularly an apparatus and method for preventing accidental electric shocks at test equipment with exposed contact bars.

BACKGROUND OF THE INVENTION

Medical equipment must be carefully tested and calibrated to ensure that it functions properly in critical situations. Electrocardiogram (ECG) testers are an example of such test equipment. As in 1 shown has an ECG tester 10 typically a number of contact bars 12 on, by means of clamps 14 can be coupled with electrode cables of an ECG monitor. The ECG tester 10 must be able to test ECG monitors with a wide variety of electrode cable clamps. Some of these cable clamps are usually clamped to bare-lead electrodes. That's why the contact bars must 12 , like the electrode terminals, are exposed and should not be isolated by an insulating structure from external contacts.

Hospital equipment, including ECG monitors, must be tested to ensure that it does not present a hazard in the form of electrical shock resulting from short-circuiting with a power cord from an AC power line. The ECG leads, and in some cases ECG monitors, are usually isolated by proper isolation of AC line voltage. This insulation can be damaged. ECG testers verify the electrical isolation of ECG monitors by applying line voltage to the contact bars 12 , The exposed contact rods 12 in prior art systems can be dangerous in that they may be accidentally touched and thereby cause fatal electric shocks. Accordingly, it would be an improvement of the art to provide a practical device and method for protecting the contact bars of ECG testers and similar equipment when not covered by an electrode terminal.

SUMMARY OF THE INVENTION

In an aspect of the invention comprises an electronic device, such as As an ECG tester, mounted on a housing contact rod with a first and a second end, wherein the first End is exposed and the second end electrically with a circuit board coupled, the workable is to apply signals to the contact rod and signals from the contact rod to recieve. An insulating sleeve is slidably mounted on the contact rod and engages a Latching mechanism which secures the sleeve in one of two positions, an extended position in which the sleeve is positioned over the contact rod is to protect the bar and isolate, and a retracted position in which the first End of the contact rod is exposed.

In Another aspect of the invention is the latching mechanism a push-push latch. On the sleeve, an attacking member be attached to allow a user to put the sleeve in the Pressed retracted and extended position.

In In another aspect of the invention, the sleeve has an opening extending transversely extends a wall thereof, so that a clamp, such. A banana plug, can attack on the first end of the contact rod when the Sleeve in the is in the extended position.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is an isometric view of an ECG tester according to the prior art.

2A - 2 B Figure 10 is an isometric view of an EKG tester with contact rod protection elements according to one embodiment of the present invention.

US 5,814,996 A. shows an apparatus for testing an electronic device for leakage currents, the device comprising: a leakage current test circuit; a Faraday cage disposed around the test circuit, the test circuit having a plurality of connectors and each of the connectors being provided; to receive a line from a device under test; a Faraday tubular cage disposed about at least one of the connectors, the Faraday cage around the connector being electrically connected to the Faraday cage around the test circuit, and means for retracting the Faraday tubular cage to connect a lead to the connector to enable.

DE 30 46 957 A1 shows an electrical contact terminal with a terminal contact element having a contact recess for receiving a first terminal conductor, and with a slidably mounted with respect to the terminal contact element and in the direction against the receiving position of the terminal conductor under spring tension and against this spring tension in an open position convertible pressure element. One with the clamping contact element conductively connected, insulated on its outer side against contact socket contact element is provided for receiving a second connecting conductor and the pressing element of the clamping element is at least on its outer surface of insulating material and at least surrounds the conductive components of the clamping element safe to touch.

US 6,231,361 B1 shows a connector for connection to a signal connector for signal transmission, which has a movable shielding sleeve to cover the bare signal line to prevent a short circuit or injury to persons. The shielded connector includes a connector head having one end, a signal line within the connector head having a lead extending outwardly from the end of the connector head, the connector head having a first notch; a button disposed in the first notch; a first spring member acting on the knob such that at least a portion of the knob extends outwardly from the connector head; a hollow shield shell having a second notch aligned with the first notch and engaged by the button to secure the shield shell to the connector head, the shield shell having an area extending beyond the end of the connector head; that the line is disposed completely within half of the shielding sleeve; an elongate third notch in the connector head; a nose extending from the shielding sleeve and engaging the elongate third notch; and a second fault element which acts on the nose.

DE 36 10 009 A1 shows an electrical connector assembly with contact protection, which includes an insulating sleeve which is retractable against the action of a spring and protects a pin against contact. A locking device which prevents unintentional pushing back of the insulating sleeve, has a two-armed lever, the first arm can be latched behind the insulating sleeve and the second arm protrudes in the latching position on the connector housing by a breakthrough of the connector housing, so that the locking device by pressure on this second arm is triggered.

EP 0 045 834 A2 shows an electrical pin, which is protected by a sliding against spring force insulating sleeve against contact. The slidable insulating sleeve is secured by an automatically engaging lock against unintentional pushing back.

3 is an exploded view of a contact rod protection according to an embodiment of the invention.

4 Figure 11 is an isometric cutout drawing of a contact bar protector mounted in an ECG tester according to an embodiment of the present invention.

5 Figure 4 is an isometric view of a housing suitable for mounting a contact bar protector according to one embodiment of the present invention.

6A - 6C Fig. 10 is a bottom plan view of a latching mechanism according to an embodiment of the present invention.

7 Figure 4 is an isometric bottom view of an alternative embodiment of protection with a truncated indexing member according to one embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Regarding 2A and 2 B In one embodiment of the invention, an ECG tester 16 a plurality of Isolierschutzelementen 18 on, the corresponding contact bars 20 are positioned around. The protective elements 18 have the form of cylindrical sleeves 30 , which can be displaced by corresponding contact rods 20 around, but other configurations can be used. The protective elements 18 can be in a retracted position, having an upper end 22 of the contact rod 20 out of the shelter 18 stick out, and in an extended position, in which the top end 22 within the shelter 18 is positioned. The upper end 22 of the contact rod 20 is shaped so that conventional ECG electrode terminals can attack it. In some embodiments, the protection extends 18 in the extended position a substantial distance over the top of the contact rod 20 also, such as B. a distance that is about equal to or greater than the length of the top of the Schut zes 18 in the retracted position below the tip of the contact rod 20 located. The protection 18 can by means of a push-push Verrastungssystems with the housing 24 be coupled, allowing an operator to a retracted protection 18 can push to spring it back to the extended position and to a pulled out protection 18 can press to lock it in the retracted position.

In some embodiments, the protection 18 an opening 26 on, extending through a wall of protection 18 extends. If the protection 18 Slightly retracted, but not far enough to the top 22 of the contact rod 20 expose, is the opening 26 in alignment with an opening 27 in the contact bar 20 is formed. As in 2 B can be shown if the protection 1 8 slightly further out of the 2A shown position, a banana plug 14b through the opening 26 in the shelter 18 and through the opening 27 in the contact bar 20 be introduced. The contact rod 20 may have a narrowed upper part 28 which is dimensioned so that it has a connecting element, such. B. an ECG clamp 14a , can receive when the protection 18 in the fully retracted position.

An attacker 32 can on the sleeve 30 be attached and create an area that a user can safely press to the sleeve 30 in the extended and retracted position 2A and 2 B to move. In the illustrated embodiment, the attacking member 32 a cross section that is for a part of its length along a direction of movement 34 of protection 18 when it moves between the retracted and extended positions is constant. The attacking member 32 For example, in the illustrated embodiment, it is substantially cylindrical. However, many other cross-sectional shapes can be used, such as. Rectangular, hexagonal, I- or H-shaped or other shape with a slot-like recess or any polygon that provides a sufficient structural shape. The attacking member 32 can by means of a fabric material 36 , which can serve the distance between the attacking member 32 and the contact rod 20 to enlarge, on the sleeve 30 be attached to reduce the risk that an operator accidentally gets an electric shock.

Regarding 3 and 4 attaches a latching mechanism 38 , such as As a push-push latching mechanism, the protection 18 either in the extended or in the retracted position. The latching mechanism may be any push-push type latching mechanism or other latching mechanism known in the art. In the illustrated embodiment, the latch mechanism 38 indexing members 40 on, on the sleeve 30 are attached. The indexing members 40 are even around the sleeve 30 spread around and can from the sleeve 30 slightly radially outward and with gaps between each two adjacent links 40 be positioned.

The indexing members 40 grab on arms 44 attached to a locking device 46 are formed. The poor 44 have beveled surfaces 48 on, allowing a press of the indexing members 40 against the arms 44 a rotation of the locking device in the direction 50 ( 4 ) causes. In the illustrated embodiment, there are twice as many indexing members 40 like arms 44 , that is, eight indexing members 40 and four arms 44 , The poor 44 can have another beveled surface 52 which is chamfered in the direction of the beveled surface 48 is opposite, so that the beveled surfaces 48 . 52 to make a point. The surface 52 is preferably substantially narrower than the surface 48 , but can be the same width. The poor 44 are on a lock body 54 attached, an opening 56 for receiving the contact rod 20 Has. A leader 58 , such as As a spring or other resilient member, engages the Sperrvorrichtungskörper 54 and pushes the beveled surfaces 48 against the indexing members 40 , In the illustrated embodiment, the biasing member extends 58 between the poor 44 the locking device body 54 and a circuit board 60 ( 4 ) on which the contact rod 20 is mounted. The circuit board 60 allows an ECG tester control circuit to apply line voltages to the contact bars 20 and for receiving signals from the contact bars 20 be. The attacking member 32 is within a channel 62 displaceable. A slidably attacking the attacking member 32 within the channel 62 can advantageously the rotational position of the indexing members 40 relative to the locking device 46 fix.

Regarding 5 can the sleeve 30 and the locking device 46 within a channel 64 with vertical guides formed therein 66 be mounted. The vertical guides 66 can be in the same number as the arms 44 the locking device 46 and be sized to hold your arms 44 slidably received. The vertical guides 66 prevent the locking device from moving in the vertical direction when the arms 44 are positioned in it. attacks 68 are between the vertical guides 66 positioned and can also be in the same number as the arms 44 the locking device 46 , The attacks 68 prevent an upward movement of the arms 44 when the arms 44 to be in alignment. The attacks 68 can have a bevelled surface, leaving the arms 44 if they are against the attacks 68 be pressed against a raised area 70 be pressed, which prevents further rotation until the arms 44 from the attacks 68 be pushed away. recesses 72 can in the attacks 68 be formed to the indexing members 40 to recieve. In the illustrated embodiments, the vertical guides are 66 through gaps between the attacks 68 educated.

Regarding 6A - 6C is, with general reference to 4 and 5 , the function of the explained locking mechanism 38 set out in more detail. If the protection 18 in the extended position are the arms 44 within the vertical channels 66 positioned as in 6A shown so that the tendon 58 can push up the protection. To move the guard 18 to the retracted position, the operator presses the engagement member 32 down, which is a press of the indexing members 40 against the chamfered upper surface 48 the locking device 46 causes, what a turning of the arms 44 over the edges of the vertical guide 66 causes, as in 6B shown. On letting go of the attacking member 32 towards the biasing member pushes 58 the bevelled upper surface 48 against the bevelled surface of the stop 68 What a rotation of the locking device and the arms 44 and their movement in alignment with another of the indexing members 40 causes it from the elevated part 70 be stopped, as in 6C shown. How out 6C obviously, will be the arms 44 so over the attacks 68 positioned to prevent them from moving upwards. For the movement from the retracted to the extended position, the operator pushes the engagement member down, causing the indexing members 40 again against the bevelled upper surfaces 48 pressed, causing a rotation of the arms 44 over the elevated part 70 and in alignment with the vertical guides 66 causes, as in 6A shown where they are on letting go of the attacker 32 can move vertically upwards.

Regarding 7 can in the embodiments in which the attacking member 32 on the protection 18 is attached, pressing on the attack element on the protection 18 applied torque 74 insofar as the attacking element 32 from the protection 18 is offset. Consequently, the indexing members can 40 tend to be relative to the bevelled upper surfaces 48 to get in misalignment. In particular, the indexing member 76 , which is located approximately at a 90 degree angle to the attacking member, when moving in the direction of rotation 78 tend to be over the surface 52 to move, giving it a force on the surface 52 exerts the direction of rotation 78 the locking device 46 is opposite. Accordingly, the indexing member 76 be shaped like a blunt, so it has no bevelled surfaces. The indexing member 76 may instead have a flat upper surface 80 have that along the direction 82 the movement of the sleeve 18 opposite the pointed ends of the other indexing members 40 is offset, leaving the flat upper surface 80 not in contact with the beveled surfaces 48 . 52 the locking device 46 comes. In the illustrated embodiment, a portion of the indexing member remains 76 and supports the latching of the protection 18 within a vertical leadership 66 or recess 72 , In an alternative embodiment, there is no indexing member that is in the position of the indexing member 76 located. In yet another alternative embodiment, the tapered surfaces 42 of the indexing member 76 have a different length, so that is different from the surfaces 42 formed tip opposite to the direction of rotation 78 shifts to the torque 74 compensate for the shift caused.

Even though the present invention with reference to the disclosed embodiments the skilled person will recognize that changes in shape and detail can be made without the mind and the Deviating scope of the invention. Such modifications are certainly in the field of ability of the specialist. Accordingly, the invention is other than by the attached ones claims not limited.

Claims (19)

An electronic device comprising: a housing ( 24 ); a contact rod ( 20 ) with a first end ( 22 ) and a second end, the second end being electrically coupled to a circuit operable to apply a voltage to the contact rod (10). 20 ), whereby the contact rod ( 20 ) and the circuit to the housing ( 24 ), the first end ( 22 ) of the housing ( 24 ) protrudes outwards; an insulating sleeve ( 30 ) slidably over the contact rod ( 20 ) is mounted; and a latching mechanism ( 38 ) attached to the sleeve ( 30 ) and the sleeve ( 30 ) selectively in a first position in which the sleeve ( 30 ) over the first end ( 22 ), and in a second position, in which the sleeve ( 30 ) below the first end ( 22 ), holds. Electronic device according to claim 1, wherein the latching mechanism ( 38 ) the insulating sleeve ( 30 ) in response to a on the insulating sleeve ( 30 ) optionally releases force. An electronic device according to claim 1, further comprising an attacking member ( 32 ), which is formed of an insulating material and laterally of the sleeve ( 30 ) protrudes. Electronic device according to claim 3, wherein the housing ( 24 ) has an elongated recess and wherein the attacking member ( 32 ) is displaceable within this elongated recess. Electronic device according to claim 1, wherein the sleeve ( 30 ) a transverse opening ( 26 ), which extends through a wall thereof, and the contact rod ( 20 ) a transverse opening ( 27 ) that has become through the contact rod ( 20 ), wherein the transverse opening ( 26 ) of the sleeve ( 30 ) in alignment with the transverse opening ( 27 ) of the contact rod ( 20 ) is when the sleeve ( 30 ) is positioned between the first and second positions. Electronic device according to claim 1, wherein the contact rod ( 20 ) a narrowed part ( 28 ), which at the first end ( 22 ) and is structured such that a clamp ( 14a ) can attack him. Electronic device according to claim 6, wherein the narrowed part ( 28 ) is exposed in the second position. Electronic device according to claim 1, further comprising a printed circuit board ( 60 ), wherein the circuit on the circuit board ( 60 ) and wherein the contact rod ( 20 ) on the printed circuit board ( 60 ) is attached and protrudes from her. Electronic device according to claim 8, wherein the printed circuit board ( 60 ) is able to perform electrocardiogram test functions. Electronic device according to claim 1, wherein the latching mechanism ( 38 ) comprises: a plurality of discrete pushers ( 40 . 76 ) attached to the sleeve ( 30 ) and circumferentially around the sleeve ( 30 ) are arranged around; one rotatable and displaceable on the contact rod ( 20 ) mounted locking device ( 46 ), wherein the blocking device ( 46 ) a plurality of arms ( 44 ) extending outwardly therefrom and circumferentially around the locking device ( 46 ) are regularly spaced around, with the arms ( 44 ) bevelled upper surfaces ( 48 . 52 ) selectively on one or more of the discrete pushers ( 40 . 76 attack); a leader ( 58 ) connected to the locking device ( 46 ) and the housing ( 24 ), wherein the biasing member ( 58 ) the bevelled upper surfaces ( 48 . 52 ) against the discrete pushers ( 40 . 76 ) presses; vertical guides ( 66 ), which are relative to the housing ( 24 ) are fixed and circumferentially around the locking device ( 46 ) are arranged around, wherein the arms ( 44 ) selectively within the vertical guides ( 66 ) are positioned, the vertical guides ( 66 ) a rotation of the locking device ( 46 ), when on the arms ( 44 attack); and vertical stops ( 68 ), which are relative to the housing ( 24 ) and circumferentially between the vertical guides ( 66 ), whereby the stops ( 68 ) selectively on the arms ( 44 ) and a vertical movement of the arms ( 44 ) in at least one direction when attacking them. Apparatus according to claim 10, further comprising an attacking member ( 32 ), which is formed of an insulating material and laterally of the sleeve ( 30 ) protrudes; with the sleeve ( 30 ) is moved along a longitudinal axis between the first and second positions; and wherein the plurality of discrete pushers ( 40 . 76 ) so circumferentially around the sleeve ( 30 ) is arranged around that none of the discrete pusher members ( 40 . 76 ) on the arm ( 44 ) of the plurality of arms ( 44 ), which has a part which extends approximately at a 90 degree angle to an angular position of the attacking member ( 32 ) is located in a first direction about the longitudinal axis, the bevelled upper surfaces ( 48 . 52 ) are aligned so that pressing the discrete pusher members ( 40 . 76 ), however, a rotation of the locking device ( 46 ) in the first direction. Apparatus according to claim 11, wherein the discrete pushers ( 40 . 76 ) a truncated discrete pusher member ( 76 ), which relative to the other discrete pushers ( 40 ) is truncated, with a portion of the truncated discrete pusher ( 76 ) at an angular position of 90 degrees from the attacking member ( 32 ) is in the first direction about the longitudinal axis. A method of preventing accidental electric shock, comprising: moving an insulating sleeve ( 30 ) from an extended position in which the sleeve ( 30 ) around a contact rod ( 20 ) and covers it, in a retracted position, in which one end ( 22 ) of the contact rod ( 20 ) is exposed; Locking the insulating sleeve ( 30 ) in the retracted position, attaching an electrode cable to the exposed end ( 22 ) of the contact rod ( 20 ), while the insulating sleeve ( 30 ) is locked in the retracted position; subsequent removal of the electrode cable from the contact rod ( 20 ); and after removing the electrode cable from the contact rod ( 20 ), Returning the sleeve ( 30 ) in its extended position. The method of claim 13, wherein the act of moving the sleeve ( 30 ) from an extended position in which the sleeve ( 30 ) around a contact rod ( 20 ) and covers it, in a retracted position from the extended position to the retracted position, moving the sleeve (FIG. 30 ) by pressing the attack member ( 32 ) having. The method of claim 13, further comprising resiliently biasing the sleeve (10). 30 ) in its extended position, so that the Action of moving the insulating sleeve ( 30 ) from the extended position to the retracted position exerting a force on the sleeve ( 30 ) against the resilient bias has. The method of claim 13, further comprising unlatching the sleeve ( 30 ), so that the resilient bias the sleeve ( 30 ) can move from the retracted position to the extended position; A method according to claim 16, wherein the act of unlocking the sleeve ( 30 ): pressing the sleeve ( 30 ) down against the resilient bias to a plurality of discrete pushers ( 40 . 76 ) circumferentially spaced from each other on the sleeve ( 30 ) are pressed so that at least one of the discrete pushers ( 40 . 76 ) against at least one bevelled upper surface ( 48 . 52 ), which at a relative to the housing ( 24 ) slidably mounted locking device ( 46 ), whereby a downward displacement of the locking device ( 46 ) against a biasing member ( 58 ) and from the attack on at least one vertical guide ( 66 ), the rotation of the locking device ( 46 ) is brought out, wherein the locking device ( 46 ) on the release from the attack on the vertical guides ( 66 ) under the action of the force of the at least one of the pressing members ( 40 . 76 ) on the bevelled upper surface ( 48 . 52 ) rotates in a first direction; and releasing the discrete pushers ( 40 . 76 ), so that the resilient bias the locking device ( 46 ) up against a stop ( 68 ), the vertical guidance ( 66 ) is positioned adjacent. The method of claim 17, wherein: the act of moving the sleeve ( 30 ) from an extended position in which the sleeve ( 30 ) around a contact rod ( 20 ) and covers it, in a retracted position from the extended position to the retracted position, moving the sleeve (FIG. 30 ) by pressing an attack member ( 32 ) having; the at least one bevelled upper surface ( 48 . 52 ) a plurality of bevelled upper surfaces ( 48 . 52 ) having; the sleeve ( 30 ) is moved along a longitudinal axis between the extended and retracted positions; and wherein the discrete pushers ( 40 . 76 ) are arranged so that none of the discrete pusher members ( 40 . 76 ) on the bevelled upper surface ( 48 . 52 ) of the plurality of bevelled upper surfaces ( 48 . 52 ) which has a part which is approximately at a 90 degree angle to an angular position of the attacking member ( 32 ) is arranged in the first direction about the longitudinal axis. The method of claim 17, further comprising: repressing the plurality of discrete pushers (FIG. 40 . 76 ), so that at least one of the discrete pushers ( 40 . 76 ) against the at least one bevelled upper surface ( 48 . 52 ), so that the locking device ( 46 ) from the attack on the attack ( 68 ) and in attack at a second, the stop ( 68 ) adjacent vertical guide ( 66 ) turns; and releasing the discrete pushers ( 40 . 76 ), so that the biasing member ( 58 ) the locking device ( 46 ) within the vertical leadership ( 66 ), whereby the discrete pushers ( 40 . 76 ) and the sleeve ( 30 ) are pressed so that they move upwards.